Lipoprotein interconversions in an insect, Manduca sexta. Evidence for a lipid transfer factor in the hemolymph

Hemolymph lipoproteins (lipophorins) of adult Manduca sexta are disinct from larval forms in density, lipid content, composition, and the presence of a third, low molecular weight apoprotein. Generally, only one lipoprotein species exists in M. sexta hemolymph during any given life stage. Progression through the life cycle results in alterations of existing lipoproteins to produce new forms, without new protein synthesis. The observed alterations in lipoprotein density could result from facilitated lipid transfer in insect hemolymph. An in vitro assay of facilitated lipid transfer was developed which employs a high density lipophorin from the wandering larva (density = 1.18 g/ml) as acceptor and adult low density lipophorin (density = 1.03 g/ml) as donor. Adult lipophorin-deficient hemolymph was shown to catalyze a time-dependent equilibration of the starting lipoproteins to produce a new intermediate lipophorin, Lp-I. Hydrodynamic experiments on the donor, acceptor, and product lipoproteins excluded fusion as the mechanism whereby Lp-I is produced. Thus, it is concluded that Lp-I results from facilitated net lipid transfer from low to high density lipoprotein. Furthermore, experiments conducted with radioiodinated donor and radioiodinated acceptor lipoproteins demonstrated that apoprotein exchange does not occur during the lipid transfer reaction. When donor lipoprotein was labeled in the lipid moiety with carbon-14, evidence of diacylglycerol and phospholipid exchange was obtained. Partial characterization of the lipid transfer factor revealed a relationship between incubation time, donor concentration, acceptor concentration, lipophorin-deficient hemolymph concentration, and transfer activity, as measured by Lp-I production. It is concluded that lipophorin-deficient hemolymph contains one or more factor(s) that catalyze net lipid transfer as well as diacylglycerol and phospholipid exchange between lipophorins to produce a single form at equilibrium.     

Isolation and characterization of the apolipoprotein E receptor from canine and human liver

Previous results have demonstrated that liver membranes possess two distinct lipoprotein receptors: a low density lipoprotein (LDL) receptor that binds lipoproteins containing either apolipoprotein (apo-) B or apo-E, and an apo-E-specific receptor that binds apo-E-containing lipoproteins, but not the apo-B-containing LDL. This study reports the isolation and purification of apo-B,E(LDL) and apo-E receptors from canine and human liver membranes. The receptors were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate and were partially purified by DEAE-cellulose chromatography. The apo-B,E(LDL) receptor was isolated by affinity chromatography on LDL-Sepharose. The apo-E receptor, which did not bind to the LDL-Sepharose column, was then purified by using an HDLc (cholesterol-induced high density lipoprotein)-Sepharose affinity column and an immunoaffinity column. Characterization of the receptors revealed that the hepatic apo-B,E(LDL) receptor is similar to the extrahepatic LDL receptor with an apparent Mr = 130,000 on non-reducing sodium dodecyl sulfate-polyacrylamide gels. The apo-E receptor was found to be distinct from the apo-B,E(LDL) receptor, with an apparent Mr = 56,000. The purified apo-E receptor displayed Ca2+-dependent binding to apo-E-containing lipoproteins and did not bind to LDL or chemically modified apo-E HDLc. Antibodies raised against the apo-B,E(LDL) receptor cross-reacted with the apo-E receptor. However, an antibody prepared against the apo-E receptor did not react with the apo-B,E(LDL) receptor. The apo-E receptor also differed from the apo-B,E(LDL) receptor in amino acid composition, indicating that the apo-E receptor and the apo-B,E(LDL) receptor are two distinct proteins. Immunoblot characterization with anti-apo-E receptor immunoglobulin G indicated that the apo-E receptor is present in the hepatic membranes of man, dogs, rats, and mice and is localized to the rat liver parenchymal cells.     

Characterization of cholesterol transport from midgut to fat body in Manduca sexta larvae

Using in vitro methods, we investigated the transfer of cholesterol from larval Manduca sexta midgut to the hemolymph lipoprotein, lipophorin, and the transfer of cholesterol from lipophorin to larval fat body. In the midgut, transfer of free cholesterol shows saturation kinetics, but the apparent Km is higher than the measured Kd for the midgut lipophorin-receptor complex. In addition, the transfer is unaffected by suramin, which binds to the receptor and inhibits lipophorin binding, and by antibodies to the lipid transfer particle, which is required for export of diacylglycerol from the midgut to lipophorin. In the fat body, transfer of free cholesterol also shows saturation kinetics, and the apparent Km is higher than the measured Kd for the fat body lipophorin-receptor complex. Suramin and anti-lipid transfer particle antibodies exert only a small (20%) inhibitory effect. In both tissues it seems that the most likely mode of cholesterol transfer is via aqueous diffusion, which is also an important mechanism in vertebrate cells. Based on these results, we propose that cholesterol homeostasis in larval M. sexta is maintained by a mass action mechanism in which cholesterol is freely transferred between lipophorin and tissues depending on the needs of the tissues. This simple mechanism is ideally suited to insects, which can neither make cholesterol nor internalize lipophorin, the two mechanisms that vertebrate cells use to control their cholesterol content.     

Transport of lipids in insects

Many insect species are almost completely dependent on lipids for their metabolic needs, although this is usually a function of developmental stage. The primary storage organ is the fat body, which can constitute 50% of the fresh weight of the insect and also acts as the major metabolic center (analogous to the vertebrate adipose tissue and liver). Bathing the fat body (and all other tissues and organs) is the hemolymph, the main functions of which are to transport nutrient substrates to utilization sites and to deliver metabolic wastes to the excretory system. Although neutral lipids are stored as triglycerides, in times of need they appear to be endergonically released into the hemolymph as diglycerides in the majority of insects thus far studied (particularly silkmoths and locusts). Indeed, diglycerides constitute the largest neutral lipid fraction in the hemolymph of silkmoths, locusts, cockroaches, bugs, etc. In the hemolymph the diglyceride is found as a constituent of specific lipoproteins, and one specific lipoprotein class (lipoprotein I; high density lipoprotein) appears to be necessary for the transport of diglyceride from the fat body cell into the hemolymph. This particular lipoprotein is also involved in the transport of cholesterol from the gut into the hemolymph. Thus, lipoprotein I appears to be the major neutral lipid and sterol transport agent in the insects studied and, in addition, plays a regulatory role in the release of both diglycerides and sterols. Hemolymph lipoprotein II (very high density lipoprotein) may be important in providing protein and lipid to the insect ovary during oogenesis. Ecdysone, the polyhydroxy steroidal insect molting hormone, is probably carried "free" in the hemolymph, although reports exist of specific hemolymph-binding proteins in some species. The other major insect growth hormone, juvenile hormone, is transported by hemolymph lipoproteins in silkmoths and locusts and by a lower molecular weight hemolymph protein in the tobacco hornworm.     

Lipoproteins in Drosophila melanogaster-Assembly, Function, and Influence on Tissue Lipid Composition

Interorgan lipid transport occurs via lipoproteins, and altered lipoprotein levels correlate with metabolic disease. However, precisely how lipoproteins affect tissue lipid composition has not been comprehensively analyzed. Here, we identify the major lipoproteins of Drosophila melanogaster and use genetics and mass spectrometry to study their assembly, interorgan trafficking, and influence on tissue lipids. The apoB-family lipoprotein Lipophorin (Lpp) is the major hemolymph lipid carrier. It is produced as a phospholipid-rich particle by the fat body, and its secretion requires Microsomal Triglyceride Transfer Protein (MTP). Lpp acquires sterols and most diacylglycerol (DAG) at the gut via Lipid Transfer Particle (LTP), another fat body-derived apoB-family lipoprotein. The gut, like the fat body, is a lipogenic organ, incorporating both de novo-synthesized and dietary fatty acids into DAG for export. We identify distinct requirements for LTP and Lpp-dependent lipid mobilization in contributing to the neutral and polar lipid composition of the brain and wing imaginal disc. These studies define major routes of interorgan lipid transport in Drosophila and uncover surprising tissue-specific differences in lipoprotein lipid utilization.     

Identification and activation of storage protein receptor of Sarcophaga peregrina fat body by 20-hydroxyecdysone

Previous work showed that 20-hydroxyecdysone activates the fat body of Sarcophaga peregrina larvae to incorporate storage protein selectively from the hemolymph. In this study, storage protein receptors of the fat body membrane which were induced on pupation or on treatment of larval fat body with 20-hydroxyecdysone in vitro were identified. The binding of storage protein to its receptor required divalent cations, especially Ca2+, and the binding was very sensitive to pH. The storage protein receptor was inactivated when the fat body membrane was treated with trypsin. The storage protein receptor is probably a protein and it may be synthesized de novo or a cryptic form may be converted to the active form when the concentration of 20-hydroxyecdysone in the hemolymph reaches a physiological level.     

Lipid uptake by insect oocytes

Approximately 30-40% of the dry weight of an insect egg consists of lipid, mostly triacylglycerol (TAG). Although this lipid is essential for the energy needed by the developing embryo, little is known about the mechanism that leads to the accumulation of TAG in the insect egg. Insect oocytes can readily synthesize TAG from free fatty acids (FFAs) and glycerol, however, de novo synthesis of FAs by the oocyte is marginal. Hence, FAs have to be imported from the fat body or the diet. Insect hemolymph contains two lipoproteins that transport lipids, lipophorin and vitellogenin. Both are taken up via endocytosis by the oocyte, however, this provides only about 10% of the egg's lipid reserves. The rest is unloaded from circulating lipoprotein particles at the oocyte surface in the form of diacylglycerol (DAG), the major lipid transport form in insects, or as FFA. The mechanism of lipoprotein unloading at the oocyte surface is currently unclear. Possible roles of the lipid transfer particle (LTP), FA transporters, and lipoprotein lipase activity are discussed.     

Isolation and characterization of juvenile hormone esterase from hemolymph of Lymantria dispar by affinity- and by anion-exchange chromatography

Juvenile hormone esterase (JHE), which catalyzes the hydrolysis of juvenile hormone, was isolated from the hemolymph of 5(th) instars of Lymantria dispar by two different procedures. One procedure was based on affinity chromatography and the other on anion-exchange chromatography. The material from both purifications showed bands of approximately 50 kDa when analyzed by SDS-PAGE. Isoelectric focusing (IEF) gels in combination with enzyme activity assays indicated two isoelectric forms with the same pI values (pH 5.1. and 5.3) from affinity purification and from anion-exchange chromatography. Amino acid sequencing of several internal peptides from the 50 kDa band following affinity purification and alignment of these sequences with JHEs from previously purified lepidopteran species (Heliothis virescens, Manduca sexta) showed high homology of these enzymes.The isolated JHE, at least in the stage of insect used, was different from the enzyme reported earlier [Valaitis, A.P., 1991. Characterization of hemolymph juvenile hormone esterase from Lymantria dispar. Insect Biochemistry 21, 583-595] to hydrolyze JH in the hemolymph of gypsy moth, based on molecular weight and amino acid sequence.     

A novel lipoprotein from the hemolymph of the cochineal insect, Dactylopius confusus.

A new type of insect lipoprotein was isolated from the hemolymph of the female cochineal insect Dactylopius confusus. The lipoprotein from the cochineal insect hemolymph was found to have a relative molecular mass of 450 000. It contains 48% lipid, mostly diacylglycerol, phospholipids and hydrocarbons. The protein moiety of the lipoprotein consists of two apoproteins of approximately 25 and 22 kDa, both of which are glycosylated. Both apolipoproteins are also found free in the hemolymph, unassociated with any lipid. Purified cochineal apolipoproteins can combine with Manduca sexta lipophorin, if injected together with adipokinetic hormone into M. sexta. This could indicate that the cochineal lipoprotein can function as a lipid shuttle similar to lipophorins of other insects, and that the cochineal insect apolipoproteins have an overall structure similar to insect apolipophorin-III.     

Insect apolipophorin III. Purification and properties

The hemolymph of adult Manduca sexta (tobacco hornworm) contains a 17,000-dalton protein that can associate reversibly with the insect lipoprotein lipophorin. The protein is abundant in the hemolymph of the adult, but is found in larval hemolymph in only small amounts, and does not associate with larval lipophorin. On the basis of its association with adult lipophorin, we have designated the protein apolipophorin III. Apolipophorin III was dissociated from adult lipophorin by guanidinium chloride treatment and isolated by gel permeation and ion exchange chromatography. The unassociated apolipophorin III was also purified from lipophorin-free hemolymph by gel permeation, ion exchange, and lectin chromatography. Both preparations have identical isoelectric points and amino acid composition as well as the following properties. Apolipophorin III is a non-glycosylated polypeptide lacking cysteine and tryptophan. The 17,000-dalton polypeptide dimerizes in solution to a protein of Mr = 34,000.     

Characterization of affinity-purified juvenile hormone esterase from the plasma of the tobacco hornworm, Manduca sexta

Juvenile hormone (JH) esterase found primarily in the hemolymph and tissues of insects is a low abundance protein involved in the ester hydrolysis of insect juvenile hormones, JHs. The enzyme was purified from the larval plasma of wild-type Manduca sexta using an affinity column prepared by binding the ligand, 3-[(4'-mercapto)butylthio]-1,1,1-trifluoropropan-2-one (MBTFP), to epoxy-activated Sepharose. The purification was greater than 700-fold with a 72% recovery, and the purified enzyme appeared as a single protein on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoelectrophoresis, reverse phase high performance liquid chromatography, and amino acid sequence analysis. The molecular weight was 66,000. The plasma JH esterase in wild-type, black, and white strains of M. sexta was similar when analyzed by immunotitration, wide range (pH 3.5-9.0) isoelectric focusing, and inhibition with MBTFP and 3-octylthio-1,1,1-trifluoropropan-2-one (OTFP). Inhibition studies revealed a sensitive and insensitive form (I50 = 10(-9) and 10(-6) M, respectively) in these three biotypes. Narrow range isoelectric focusing (pH 4.0-7.0) indicated the presence of two major isoelectric forms with pI values of 6.0 and 5.5, but their inhibition kinetics with OTFP and O,O-diisopropyl phosphorofluoridate were identical.     

免疫亲和层析法纯化棕尾别麻蝇(Sarcophagaperegrina)幼虫血淋巴凝集素

 报道了利用免疫亲和层析法纯化棕尾别麻蝇幼虫血淋巴凝集素的结果．哺乳动物红细胞能够特异地吸附凝集素．用兔红细胞与麻蝇幼虫血淋巴凝集素形成的复合体免疫供血家兔,得到麻蝇幼虫血淋巴凝集素的抗体．再利用抗体制备亲和吸附柱,通过免疫亲和层析一次性纯化了麻蝇幼虫血淋巴凝集素． Ｓ Ｄ Ｓ Ｐ Ａ Ｇ Ｅ结果显示,该凝集素的分子量约为７３ ｋ Ｄ．这一结果,与用对麻蝇幼虫血淋巴凝集素有抑制作用的糖蛋白—胎球蛋白和甲状腺球蛋白为配基,亲和层析纯化的结果完全相同,表明用这种免疫亲和层析法纯化凝集素是可行的．为不清楚专一性识别糖或专一性识别糖不典型,难于用普通亲和层析纯化的凝集素,提供了一种有效的纯化方法．     

Purification and characterization of honey bee vitellogenin

A protocol has been developed for the purification of vitellogenin from the honey bee, Apis mellifera. Purification allows for the first characterization of a vitellogenin from the large order Hymenoptera. Hymenopteran vitellogenins are unusual among insect vitellogenins in that they contain only one type of apoprotein. The honey bee vitellogenin was isolated from hemolymph of honey bee queens by a combination of density gradient ultracentrifugation, ion-exchange chromatography, and affinity chromatography. The native vitellogenin particle is a very high density glycolipoprotein containing approximately 91% protein, 7% lipid, and 2% carbohydrate. Phospholipid and diacylglycerol are the major lipid components. The equilibrium density (1.28 g/ml) is the same as that for Manduca sexta vitellogenin, which contains a much higher proportion of lipid. The covalently bound carbohydrate moiety of the particle is high in mannose. The amino acid composition of vitellogenin is similar to those of vitellogenins from other insect species. The N-terminal amino acid sequence of the apoprotein was determined, the first such sequence for any insect vitellogenin. When analyzed by sodium dodecyl sulfate (SDS)-gel electrophoresis, A. mellifera vitellogenin resolved into a single band with an apparent Mr of 180,000. Gel filtration under reducing and native conditions yielded estimated Mr values of about 300,000.     

Isolation and characterization of lipophorin from Drosophila melanogaster larvae

The hemolymph lipoprotein lipophorin has been isolated from third-instar Drosophila melanogaster larvae by a technique that involves homogenization of whole larvae in a medium containing protease inhibitors and purification of the lipoprotein by density gradient centrifugation. Drosophila lipophorin has a density of 1.16 g/ml and is composed of 62.5% protein, 23.1% phospholipid, 7.4% diacylglycerol, 5.4% triacylglycerol, 0.9% hydrocarbon, and 0.7% sterol. As is the case with other insect lipophorins, Drosophila lipophorin contains two apolipoproteins, apolipophorin-I (M_r ≈ 275,000) and apolipophorin-II (M_r ≈ 76,000). Drosophila apolipophorin-I does not crossreact with antibodies prepared against apolipophorin-I from Manduca sexta.     

昆虫卵黄原蛋白受体的研究进展

昆虫卵黄发生的一个重要过程是卵黄蛋白的摄取,已有的研究表明脂肪体合成的卵黄原蛋白(vitellogenin,Vg)是通过受体介导的内吞作用(receptor mediated endocytosis,RME)被正在发育的卵母细胞所摄取。昆虫卵黄原蛋白受体(vitellogenin receptor,VgR)是介导昆虫卵黄原蛋白胞吞作用主要受体,它属于低密度脂蛋白家族,在结构与特性上具低密度脂蛋白家族的共性。卵黄原蛋白及其受体在昆虫生殖过程中起着重要的作用,本文综述了昆虫VgR的基本特性、分子结构及表达调控等方面的研究进展。     

Purification of insect vitellogenin and vitellin by gel-immobilized ferric chelate.

Vitellogenin and vitellin of Manduca sexta and some other insect species were purified by immobilized metal ion affinity chromatography. Ferric ion was chosen as the immobilized metal ion. Agarose-bound carboxymethylpicolylamine was used as the chelating adsorbent for the ferric ion. Vitellogenin and vitellin, both phosphorylated lipoproteins, were shown to bind specifically to the iron. The general applicability of immobilized ferric ion affinity chromatography for the purification of insect vitellogenin and vitellin is suggested.     

Purification of a sarcoplasmic reticulum protein that binds Ca2+ and plasma lipoproteins

A protein in the sarcoplasmic reticulum of rabbit skeletal and cardiac muscle was identified because of its ability to bind 125I-labeled low density lipoprotein (LDL) with high affinity after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This protein, referred to as the 165-kDa protein, is restricted to striated muscle. It was not detected in 14 other tissues, including several that contain smooth muscle, but it appears in rat L6 myoblasts when they differentiate into myocytes. Immunofluorescence and immunoelectron microscopic studies revealed that the protein is present throughout the sarcoplasmic reticulum and the terminal cisternae. It binds 45Ca2+ on nitrocellulose blots and stains metachromatically with Stains-all, a cationic dye that stains Ca2+-binding proteins. It does not appear to be a glycoprotein, and it appears slightly larger than the 160-kDa glycoprotein previously described in sarcoplasmic reticulum. The 165-kDa protein binds LDL, beta-migrating very low density lipoprotein, and a cholesterol-induced high density lipoprotein particle that contains apoprotein E as its sole apoprotein with much higher affinity than it binds high density lipoprotein. The protein is stable to boiling and to treatment with sodium dodecyl sulfate, but it becomes sensitive to these treatments when its cystine residues are reduced and alkylated. The protein was purified 1300-fold to apparent homogeneity from rabbit skeletal muscle membranes. It differs from the cell surface LDL receptor in that 1) its apparent molecular weight is not changed by reduction and alkylation; 2) it is present in Watanabe-heritable hyperlipidemic rabbits, which lack functional LDL receptors; 3) binding of lipoproteins is not inhibited by EDTA; and 4) it is located within the lumen of the sarcoplasmic reticulum where it has no access to plasma lipoproteins. It is unlikely that this protein ever binds lipoproteins in vivo; however, its lipoprotein binding activity has facilitated its purification to homogeneity and suggests that this protein has unusual structural features. The role of the 165-kDa protein in Ca2+ homeostasis in the sarcoplasmic reticulum, if any, remains to be determined.     

Separation of insect hemolymph proteins by cascade-mode multi-affinity chromatography.

The hemolymph of the adult female Manduca sexta was fractionated by cascade-mode multi-affinity chromatography (CASMAC) on a main-line tandem column chain containing Zn(2+)-TED, T-gel, Ni(2+)-DPA, and phenylsepharose and a side-line column containing Zn(2+)-DPA. The technique separated some of the previously described major hemolymph proteins, and yielded a number of fractions with simple composition. Some of these fractions contained only less abundant proteins of Manduca hemolymph. Thus, it appears that CASMAC would be a very useful fractionation technique for purification and characterization of the minor proteins of insect hemolymph.     

Musca domestica larval lipoprotein

A larval specific high-density lipoprotein (HDL) has been isolated from Musca domestica hemolymph by a combination of density gradient and glycerol gradient ultracentrifugations. The larval lipoprotein has a density of 1.134 g/ml and is formed by at least four apoproteins with molecular weights equal to 26,000, 23,000, 21,000, and 20,000. This lipoprotein contains large amounts of hydrocarbons and phospholipids and minor amounts of diacylglycerols and cholesterol. The larval lipoprotein is completely distinct from lipophorin in regard to apoprotein composition, lipid moiety, physiological pattern, and immunological reactions. Larval lipoprotein is accumulated until the end of the feeding period. During the pupal molt this protein is utilized and is no longer detected after 2 days of pupal stadium. The results obtained imply a possible role of this protein in the puparia and/or pupal cuticle formation. Judging from the properties shown, the Musca domestica larval lipoprotein is a completely new type of insect lipoprotein.     

Major hemolymph proteins from larvae of the black swallowtail butterfly,Papilio polyxenes

Three major hemolymph proteins of Papilio polyxenes larvae were isolated and characterized. Density gradient ultracentrifugation of hemolymph resulted in flotation of the major lipoprotein, lipophorin. P. polyxenes larval lipophorin is composed of two apoproteins, apolipophorin-I and apolipophorin-II, plus a mixture of lipids, to give a density of 1.13 g/ml. Immunoblotting experiments using antisera directed against Manduca sexta apolipophorin-I and apolipophorin-II, respectively, revealed cross-reactivity of apoLp-I with Manduca sexta apoLp-I, and apoLp-II with M. sexta apoLp-II. Gel permeation chromatography of the subnatant obtained following density gradient ultracentrifugation revealed the presence of a major protein peak which was shown to contain three major serum proteins, two of which were isolated and characterized. One of these proteins was purified by lectin affinity chromatography. Both proteins have native molecular weights in the range of 450,000 and appear to be hexamers of a single subunit type. Major serum protein-1 is nonglycosylated and has a subunit molecular weight of 75,000. Major serum protein-2 is glycosylated and has a subunit molecular weight of 74,000. Amino acid analysis of this protein revealed a tyrosine plus phenylalanine content of 20 mole percent, characteristic of the arylphorin class of insect storage proteins. Using antibodies against M. sexta larval hemolymph proteins, both the P. polyxenes major serum proteins were shown to be immunologically related to serum proteins of other lepidopteran species.